The interplay of insulating and superconducting orders in magic-angle graphene bilayers

The recent discovery of superconducting and correlated insulating states coexisting in magic-angle twisted bilayer graphene (MAG) at commensurate fillings have raised fascinating questions about the interplay of these orders. Tuning electron-electron inter-actions in MAG would shed light on the individual roles of these phases and their intri-cate relationship. Here we report on a new method to control electronic interactions in a correlated system, by varying the separation of a metallic screening layer in ultra-close proximity to a MAG layer. We observe that correlated insulators disappear when the separation becomes smaller than the extent of Wannier orbitals, w 0.5 tesla, exhibiting Chern bands with quan-tized Hall resistance of h/2e2 consistent with orbital magnetism. Our study establishes direct and independent control of the insulating and superconducting phases, pointing to their possibly distinct microscopic origin. The re-examination of the often-assumed mother-child relation between these phases, triggered by these observations, illustrates a new technique to directly probe microscopic mechanisms of anomalous superconductivity in MAG and other strongly-correlated systems.